Dynamics of residential indoor gas- and particle-phase water-soluble organic carbon: measurements during the CASA experiment.

IF 4.3 3区环境科学与生态学 Q1 CHEMISTRY, ANALYTICAL Environmental Science: Processes & Impacts Pub Date : 2024-10-07 DOI:10.1039/d4em00340c

Marc Webb, Glenn Morrison, Karsten Baumann, Jienan Li, Jenna C Ditto, Han N Huynh, Jie Yu, Kathryn Mayer, Liora Mael, Marina E Vance, Delphine K Farmer, Jonathan Abbatt, Dustin Poppendieck, Barbara J Turpin

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Abstract

Previous time-integrated (2 h to 4 h) measurements show that total gas-phase water-soluble organic carbon (WSOC_g) is 10 to 20 times higher inside homes compared to outside. However, concentration dynamics of WSOC_g and total particle phase WSOC (WSOC_p)-are not well understood. During the Chemical Assessment of Surfaces and Air (CASA) experiment, we measured concentration dynamics of WSOC_g and WSOC_p inside a residential test facility in the house background and during scripted activities. A total organic carbon (TOC) analyzer pulled alternately from a particle-into-liquid sampler (PILS) or a mist chamber (MC). WSOC_g concentrations (215 ± 29 μg-C m^-3) were generally 36× higher than WSOC_p (6 ± 3 μg-C m^-3) and 20× higher than outdoor levels. A building-specific emission factor (E_f) of 31 mg-C h^-1 maintained the relatively high house WSOC_g background, which was dominated by ethanol (46 μg-C m^-3 to 82 μg-C m^-3). When we opened the windows, WSOC_g decayed slower (2.8 h^-1) than the air change rate (21.2 h^-1) and E_f increased (243 mg-C h^-1). The response (increased E_f) suggests WSOC_g concentrations are regulated by large near surface reservoirs rather than diffusion through surface materials. Cooking and ozone addition had a small impact on WSOC, whereas surface cleaning, volatile organic compound (VOC) additions, or wood smoke injections had significant impacts on WSOC concentrations. WSOC_g concentration decay rates from these activities (0.4 h^-1 to 4.0 h^-1) were greater than the normal operating 0.24 h^-1 air change rate, which is consistent with an important role for surface removal.

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住宅室内气相和粒相水溶性有机碳的动态变化：CASA 实验期间的测量结果。

以往的时间积分（2 至 4 小时）测量结果表明，室内的气相水溶性有机碳总量（WSOCg）比室外高 10 至 20 倍。然而，人们对水溶性有机碳 (WSOCg) 和总颗粒相水溶性有机碳 (WSOCp) 的浓度动态并不十分了解。在 "表面和空气化学评估"（CASA）实验中，我们测量了住宅测试设施内 WSOCg 和 WSOCp 在房屋背景和脚本活动期间的浓度动态。总有机碳（TOC）分析仪交替从颗粒液体采样器（PILS）或雾室（MC）中提取有机碳。WSOCg 浓度（215 ± 29 μg-C m-3）比 WSOCp 浓度（6 ± 3 μg-C m-3）高出 36 倍，比室外水平高出 20 倍。31 mg-C h-1 的建筑物特定排放因子（Ef）维持了相对较高的室内 WSOCg 背景，其中主要是乙醇（46 μg-C m-3 至 82 μg-C m-3）。当我们打开窗户时，WSOCg 的衰减速度（2.8 h-1）比换气速度（21.2 h-1）慢，而 Ef 则增加了（243 mg-C h-1）。这种反应（Ef 增加）表明，WSOCg 的浓度是由近表面的大型储层调节的，而不是通过表面材料扩散的。烹饪和臭氧添加对 WSOC 的影响较小，而表面清洁、挥发性有机化合物 (VOC) 添加或木质烟雾注入则对 WSOC 浓度有显著影响。这些活动产生的 WSOCg 浓度衰减率（0.4 h-1 至 4.0 h-1）大于正常运行时的 0.24 h-1 换气率，这与表面清除的重要作用是一致的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environmental Science: Processes & Impacts CHEMISTRY, ANALYTICAL-ENVIRONMENTAL SCIENCES

CiteScore

9.50

自引率

3.60%

发文量

202

审稿时长

1 months

期刊介绍： Environmental Science: Processes & Impacts publishes high quality papers in all areas of the environmental chemical sciences, including chemistry of the air, water, soil and sediment. We welcome studies on the environmental fate and effects of anthropogenic and naturally occurring contaminants, both chemical and microbiological, as well as related natural element cycling processes.